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Transcript
DRAGON GENETICS LAB -- Principles of Mendelian Genetics Adapted from: Dr. Pamela Esprivalo Harrell, University of North Texas, developed an earlier version of "Dragon Genetics" which is described in the January 1997 issue of Science Scope, 20:4, 33-37. Copyright 2005, Bob Farber, Central High School, Philadelphia, PA BACKGROUND Students will work in pairs in the lab to produce a dragon from the random mixing of genetic traits. Each student will be a surrogate dragon parent. They will pick up a complete set of dragon chromosomes. Surrogate dragon parent partners must be of the opposite sex, therefore one parent must pick up the double X chromosomes while the other must pick up the X/Y chromosomes. The homologous chromosomes will be separated according to Mendel’s law of Independent Assortment. The genetic codes that are passed on to the baby will be recorded on the following pages. The surrogate parents must then decode the genes inherited by their bundle of joy to determine the phenotype traits of their baby. Using the pictures at the end of the handout, they will cut out these traits and paste them together to have a picture of their baby. PROCEDURE 1. You will work with the partner that you are sitting with. You and your “spouse” will create one dragon. Each of you will fill out a sheet and draw your baby. This is a no divorce classroom. The lab must be completed on time. 2. Each partner must pick up five Popsicle sticks -- one of each color of chromosome (red, orange, green, yellow) and one sex chromosome stick (one person needs a blue, one needs a pink). Each side of a stick represents a chromosome, and the two sides together represent a pair of homologous chromosomes (one from mom and one from dad). 3. For each chromosome, record the Mom and Dad genotypes on the data chart. 4. For each color chromosome and then for the sex chromosomes, each parent will randomly drop his or her stick on the table. The side of the stick that is up represents the chromosome that is passed on to the baby. 5. The alleles from each pair of homologous chromosomes will be recorded in the data chart on pages 3-4. 6. The decoding chart on page 2 indicates the phenotypic effect of each gene. The trait produced by each pair of alleles should be recorded in the data chart. Remember that a CAPITAL letter is dominant over a small letter [recessive] unless the decoding chart indicates those traits are codominant (incomplete dominant), sex-influenced, or sex-limited. 7. Not all traits will turn out nicely. If you have a letter that is not supposed to be in that space (inversion) or you are missing a letter (deletion), you have a mutation. For a mutation you must create a mutated trait for the ROW it is in. Example: If the genotype for the head flaps is CD, I may say my phenotype is two head flaps. 8. The students will use the pictures of dragon trait on page 5 to produce a picture of the baby. Students may trace, cut and glue, or draw the traits from the pictures provided. 9. Color the baby appropriately. 10. Each person will turn in the data charts, a picture of the baby, and the questions answered in complete sentences on a separate sheet of paper. DRAGON GENOME DECODING OF THE GENES Chromosome Dominant genes Recessive genes Green Chromosome A. no chin spike a. chin spike B. nose spike b. no nose spike C. three head flaps c. four head flaps D. no visible ear hole d. visible ear hole E. [see below] ___________________________________________________________________________________ Red Chromosome F. long neck f. short neck G. no back hump g. back hump H. no back spikes h. back spikes I. long tail i. short tail J. flat feet j. arched feet _______________________________________________________________________________ Orange Chromosome K. red eyes k. yellow eyes L. spots on neck l. no spots on neck M. [see below] N. no fang n. fang O. spots on back o. no spots on back ______________________________________________________________________________ Yellow Chromosome P. no spots on thigh p. spots on thigh Q. green body q. purple body R small comb on head [see below] r. large comb on head S. [See below] T. [See below] ______________________________________________________________________________ Sex Chromosomes U. regular thigh u. pointed thigh V. four toes v. three toes X Chromosome Only W. no chest plate w. chest plate X. no. tail spike x. tail spike Z. long arms z. short arms + non-fire breather - fire breather Y chromosome only Y. male sex Codominant (Incomplete Dominant) traits E. eye pointed at each end S. Red spots e. round eye s. yellow spots Ee. eye round at front only Ss. orange spots Sex-influenced traits M. wings T. no elbow spike m. no wings [dominant in presence of male hormone] t. elbow spike [dominant in presence of male hormone] Sex-limited traits R or r Only males have the comb on the head. Our Baby! Names _________________ _________________ Green Chromosomes GENOTYPES MOM DAD Alleles in Egg Sperm TRAIT---Phenotype of Baby Red Chromosomes GENOTYPES MOM DAD Alleles in Egg Sperm TRAIT---Phenotype of Baby Orange Chromosomes GENOTYPES MOM DAD Alleles in Egg Sperm TRAIT---Phenotype of Baby Yellow Chromosomes GENOTYPES MOM DAD Alleles in Egg Sperm TRAIT---Phenotype of Baby Sex Chromosomes GENOTYPES MOM DAD Alleles in Egg Sperm TRAIT---Phenotype of Baby Analysis 1. What is the law of segregation? 2. Give an example from this activity of the law of segregation. 3. What is the law of independent assortment? 4. What did we do in this activity to demonstrate the law of independent assortment? 5. The gene for fangs is recessive, yet most of the dragons have fangs. How can this happen? [Hint. The gene that causes dwarfism (achondroplasia) in humans is dominant, yet most humans are not dwarfs.] 6. If you have a mutation (gene deletions or inversions in the chromosomes), note the phenotype for each of your mutated traits. i.e. CD - Two head flaps. 7. What is the sex of your baby? 8. What is a sex-linked trait? 9. What traits did your baby have that were sex-linked? 10.What traits are more likely to be found in males? [Consider sex-linked, sex-influenced and sexlimited traits.] 11.How might these be an advantage to this sex? [Be creative in your answers.] 12.What traits are more likely to be found in females? 13.How might these be an advantage to this sex?